Amplifier-electrical control system



Jan. 13, 1959 w. D. GABOR ETAL 2,368,896

AMPLIFIER-ELECTRICAL CONTROL SYSTEM Filed March 4, 1953 s Sheets-sheaf. 1

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ATTORNEYS Jan. 1959 w. D. GABOR ET AL AMPLIFIER-ELECTRICAL. CONTROL SYSTEM 3 Sheets-Sheet 3 Filed March 4, 1953' 61425;; Mm 42M.

ATTORNEY-5" United States Patentf) 2,868,896 AMPLIFIER-ELECTRICAL CONTROL SYSTEM William D. Gabor, Norwalk, and Joseph L. Stahovec, 'Springdale, Conn., assignors to C. G. S. Laboratories,

Inc, Stamford, Conn.

Application March 4, 1953, Serial No, 340,352 14 Claims. (Cl. 179--171) This invention relates to electrical'control apparatus and more particularly to arrangements for controlling the current through a reactive circuit so that it is an exact replica of a control voltage.

Such apparatus is useful, as onejexample, in connection with saturable reactance devices. These devices have an inductive control Winding which exerts its control influencc as a function of the current through it. This current, however, may not be a true replica ofthe voltage applied to the terminals ofthe control winding. There are several possible reasons for this: With control signals containing alternating current components, the inductance of the winding modifies the shape of the current wave; even with D.-C. control signals, changes in the resistance vof the winding with changes in temperature will cause an undesired variation in the control current. Various methods have been proposed for correctingfor this nonlinearity in alternating current systems and other methods have been proposed for use in direct current systerns'; but no entirely practical systemhas been'provided for handling both alternating and direct=current control signals. j

In a preferred embodiment of the present invention, the control voltage is fed into a direct current amplifier which is arranged tocontrol the current through a control tube connected in series with the control winding of}. satin-able reactor or other reactive circuit orel'eriient. Aseparate load resistor also in series with the control tube develops anegativc feedback voltagethatjis applied to the input circuit of the D.- c. amplifier. The current through the control tube is thereby maintained as a linear function of the applied control voltage. This causes the current through the control winding 'to have the same linear relationship provided all of thccontrolled current of the tube flows through the control winding as would be true if a triode tube were used.

it is desirable, howevento use a pentode rather than a triode as the control tube because of its higher gain, that is, less driving voltage is required, and because it can be operated at higher frequencies. If thecontr'ol winding is connected in series with the anode of the tube, the screencurrent of the tube doe's not flow through the control Winding: this introduces a relatively large error into the system. The magnitude, of this error changes with change in the magnitude of the input signal; also there is considerable variation in the magnitudes of the screen currents of different tubes operating under identical conditions.

In accordance with thepresent invention, this difficulty is solved by arranging the pentode tube so that both the screen and plate currents flow through the control Winding while maintaining the desired linear control of the tube current.

Such a control system is applicable to many types of devices such as precision magnetic-type deflection systems for deflecting electron beams in television tubes, radar display tubes, storage tubes, electron;bea1n com: puter or gating tubes. etc. The control of fiuxin ferrogreases hatented Jan. l3 TQEQ ice in the light ofthe following detailed description of various embodiments of the invention as illustrated in the accompanying drawings, in which:

Figure 1 represents schematically a control system embodying the invention;

Figure 2 shows a modification of the system of Figure l using only a single control tube;

Figure 3 shows another arrangement similar to Figure 1 and particularly useful in applications requiring high sensitivity and maximum stability; and

Figure 4 shows the circuit arrangement of Figure 3 as incorporated in a sweep receiver.

In Figure 1, a controllable inductor 2 is illustrated as the device to be controlled. This may be, for example, a conventional saturable reactor or it maybe a controllable inductor of the type described by Dewitz in U. S. patent application Serial No. 213,548, filed March 2, 1951', and having a ring core 4 of ferromagnetic ceramic material, such as ferrite. V p

A signal winding 6 is wound on the core 4 andis connected to the circuits to be controlled as indicated in block form at 8. The winding 6 maybe formed in indicated in block form at 12, the signal from the output terminals 14 and 16 are applied to the input terminals 18 and 20 of a D.-C. amplifier 22; the terminals 14 and 18 are connected together throughan isolation resistor 24 and the terminals 16 and 20 are connected together through the common ground circuit. The amplifier 22 may be of conventional construction such as to handle control signals of Whatever characteristics are being used.

The output terminals 26 and 28 of the amplifier 22 are connected respectively to the common ground circuit and to the control grid 30 of a pentode-type control tube 32. This tube is connected in series with the impedance whose current is to be regulated and the magnitude of this current is controlled by the potential produced on the grid 30 by the amplifier 22.

The cathode 34 of this tube is connected through a resistor 36 to the common ground circuit; its suppressor grid 38 is connected directly to the cathode 34; and its anode 40 is connected through the winding 10 and a lead 42 to a positive-voltage supply terminal 44 of a conventional rectifier-filter power supply 46. The negativevoltage supply terminal 48 of this power supply is connected to the common ground circuit. The power supply is energized in the usual manner from alternating-current power mains 50. e

Thevoltage developed across the cathode resistor 36 is fed back to the input of the amplifier 22 as a negative feed-back signal by means of a lead 52 and an isolation resistor 54 connected betweenthe cathode. 34 and the input terminal 18 of the amplifier 22. This feed-back signal reduces the gain of the amplifier 22, for example substantially to unity, so that the current. through the resistor 36 and the tube 32 is a linear function of the control voltage delivered by the source 12. However, this tube current includes both the plate current and the age-dropping resistor to the terminal 44, any variation in the screen current would cause an error in therelationship between the current through the Winding 1 and'the control voltage. Such an arrangement is, not satisfactory even when a well-regulated power supply is provided.

In order to overcome this difficulty, both the screen current and the plate current are caused to flow through the winding 10. In the embodiment of Figure 1,. the anode 40 is connected to the anode 58 of a triode tube 60 whose cathode 62 is connected to the screen grid 56 of the tube 32. Bias voltage for the control grid 64 of the tube 60 is provided by a voltage divider consisting of a fixed resistor 66, a potentiometer 68, and a second fixed resistor 70 connected in series between the positive supply lead 42 and ground- The adjustable contact 71 of the potentiometer 68 is connected to the control grid 64. The screen-grid current of tube 32 thus flows from the anode 40 through the tube 60 to the screen grid 56.. The magnitude of the screen voltage is controlled by the bias voltage maintained on the grid 64 of the tube 60 and the voltage of the screen grid 56 will be higher by a few volts than the control grid 64 of the tube 60. The tube 60 must have sufficient capacity to handle the screen current of the tube 32 and should have low plate resistance and high mutual conductance. With this arrangement, the variation in the screen voltage with respect to ground can be held to less than one percent. 1

In some instances, it may be desirable to add a voltage regulator tube, indicated in broken lines at 72. This regulator tube may be a conventional gaseous type regulator tube with a heated cathode or it may be a cold cathode gaseous discharge tube such as an ordinary neon lamp. The regulator tube is connected between the control grid 64 of tube 60 an d the common ground circuit.

Figure 2 shows an arrangement using only one tube and which is not generally so satisfactory as the system of Figure 1, but which is useful in particular applications. In this figure, certain parts having functions corresponding to the functions of parts of Figure 1 have been given corresponding reference numerals followed by the suffix A.

The impedance, illustrated diagrammatically at 2A, whose current is to be controlled is connected, as previously described, in series with the positive-voltage supply lead 42A and the anode 40A of the pentode tube 32A. The screen grid 56A is connected through a resistor to the anode 40A, and no auxiliary triode tube is used. As before, both the screen and plate currents flow through the impedance 2A and good linearity is maintained. However, the screen voltage now fluctuates as the current through the tube changes. When the signal voltage applied to the control grid 30A changes in a negative direction to decrease the current through the impedance 2A, the voltage on the screen grid 56A increases, thus tending to cause the plate current to increase and to partially offset the effect of the signal voltage. When the control voltage on grid 30A becomes more positive to increase the current through the impedance 2A, the screen-grid voltage becomes less positive, thus tending to oppose the change produced by the control grid. This results in lower sensitivity of the system, that is, a greater change in control voltage is required to produce a given change in the current through the im: pedance 2A than is required with the arrangement of Figure l. I

The sensitivity of the system of Figure 2 can be im proved somewhat by the addition of the regulator tube 72A connected between the screen grid 56A' and the cathode 34A. However, this limits the operating range of the system. When the plate current is high, the voltage at the screen 56A may be insufficient to maintain'the ignition of the tube 72A which therefore loses control.

asse

Thus, the screen grid 56 of this i When the plate current of -"continues to flow through the impedance 2A, the resistor 74, and the regulator tube 72A. Thus, a certain amount of unregulated current always flows through the impedance 2A. In spite of these disadvantages, the systems represented by Figure 2 will be found advantageous in applications where these particular limitations are not important.

The sensitivity of the system shown in Figure 1 can be improved further if the screen voltage can be made to change in the same direction asthe control grid voltage; that is, the screen grid is made to function as a control element to assist the change introduced by the control grid. One way of doing this is shown in Figure 3, which shows a modified arrangement of Figure 1 and in which certain corresponding parts have been given the same reference numerals followed by the sufiix B.

The amplifier 22B of Figure 3 may be identical with the amplifier 22 of Figure 1 except that an additional output terminal 76 is provided which is connected to the anode 78 of the final tube 80 of the amplifier 22B. The pentode tube 32B is connected to the amplifier 22B and the impedance 2B inithe same way as in Figure 1. The

power supply 46B is shown with an additional negative voltagesupply terminal 82 that is connected to the amplifier 223 in order to maintain the correct bias voltage on the control grid 30B, which is connected to the junction of two resistors 84 and 86 connected in series be tween the anode 78 of tube 80 and the negative supply terminal 82.

The a'uxiliar screen-control tube 60B is connected as before in series between the anode 40B and the screen grid 56B of the tube 32B. However, the control grid 64B of the tube 60B is now connected to the anode 78 of the amplifier tube 80. With this arrangement, when the control grid 30B of the tube 323 changes in a negatrol circuit of Figure 3 as incorporated in a sweep frequency device. The windings 60 of the controllable inductor 2C, for example, may form part of a resonant circuit. If a sawtooth wave form from the generator 12C is applied through the amplifier 22C to the control circuit, the resonant frequency of the circuit incorporating the winding 6C may be made to rapidly scan a predetermined range of frequencies. A D.-C. voltage forming source indicated at may also be applied to the amplifier and will permit adjustment of the center frequency about which the frequency of the circuit incorporating the winding 6C sweeps. One output terminal 102 of the generator 12C is connected to the common ground circuit and its other output terminal 104 is connected through a capacitor 106 and a resistor 108, connected in parallel with a condenser 110, to a control grid 112 of a triode vacuum tube 114 which forms the first stage of the amplifier 22C. A potentiometer 116 is connected across the output terminals of the D.-C. voltage source 100 and the adjustable contact of this potentiometer is connected through a resistor 119 to the control grid 112. The magnitude of the D.-C. voltage relative to ground therefore can be adjusted by means of the potentiometer 116 so as to change the frequency of the controlled cir' cuit as mentioned above. The cathode 118 of the tube 114 is connected to ground through a bias resistor 120 130 is: connected between thew anode 122 and a negative voltage supply: lead: 136 which is: connected toia'wnegative output terminal 138 to the power supply 46C. A third -.output;.ter-minal 140:of the powersupply 460. is connected. to;;thecommon ground" circuit, which is maintained -atya,potential between thezpotentials of the output terminals 128 and 138;.

The; junction; of the resistors 13.0'and 132: is connected directlyto a control grid- 1314 of the/twin triode vacuum tube 136. .Thetcathoideslfisz and 140 of the two sections ofithisrtube are connected-together and through a common bias, resistor 142 to the negative voltage supply lead 136.

The-anode 1440f the first. section of: this triode is connected through twotresistors 146=and148 to the positive voltage supply-lead126. .A voltage dividing circuit comprising a resistor,150;;a.potentiometer 152, anda second resistors84C and 86C and a condenser 160 connected in parallel with the resistor 84C to the negative voltage supply. lead 136. Theoutput terminalZSC at the junction of the resistors 84C and 86C is connected directly to the control grid 30C of the tube 32C.

In order to handle the. current for the controllable inductor-g 2C, a second tube, generally indicated at 162, identical with the tube 32C, has eachof itselements connected .in parallel W-iththecorrespondingtelement of the tube 32C. Suppressor resistors 164 and 166, however, are. provided in. the circuit connection between the two anodes and .betweenthej two control grids, respectively. Otherwise, the tube 32C is connected and operates substantially in the-manner described in connection with Figure 3. The tube 60C is illustrated in the form ofa twinitriodevacuumtube with the corresponding eleinents of each section. of the tube connected. in parallel to increase the currentfhandling capacity of the tube. In other respects, the tube is connected identically with and operates in the same manner. as the corresponding tube shown .in Figure 3.

The. feed-back circuitfrom the cathode 34C of'the tube-32C is connected. through two phase-compensating networks 168. and 17:0 tofthe control grid 112 of the input tube 114 of the amplifierZZC. The phase shift network 168 is formed by...a.resistor l72connected in parallel with a variable condenser 174. The other phase shift network 170 comprises a fixed resistor 176 connected in parallel withyariable condenser 178. These phase shift networks correct the. phase. of the feed-back voltage source to correchfor. phase shifts .which occurred in the amplification andcontrol tube circuits. Ordinarily,

satu'rable reactors and controllable inductors in themselves have a non-linear control characteristic so that it is desirable to introduce a compensating characteristic into the amplifier circuit so that linearity of the controlled currents can beobtained. For this purpose, a twin diode 180is connected between the junction of the phase shiftnctworks 168Qandf170 and the ground circuit and is arranged so that as the amplitude of the feed-back voltageincreases, the percentage feed-back is reduced,

"thereby allowing the amplifier to have increased gain and thereby proportionately increasing the control current. The anodes 182 and 184 of these diodes are cor1- 'nectcd together and to the junction of the phase shift networks 168and170; The anodes 186and 188 are connectedrespectively through resistors 19!) and 192 to the commonground-circuit. The twodiodes are biased of the diodes startsto conduct, thus reducing somewhat the eifectiveness 0f the feed-back network, and at a somewhat highervoltage the other diode. starts to conduct, thus further decreasing the elfectiveness of the feed-back network. The values at which these resistors are adjusted .will. depend upon the particular characteristics of the control mechanism.

In one particular embodiment, the components shown in Figure 4 had the following values:

Name Reference Value Character Condenser. 4 mieroiarads.

D 220 mTl'lf.

7 to 45 mmf.

50,010 ohms. 103.010 ohms 40100 ohms. 103.000 ohms. 30.030 ohms. 15.070ohm3. 13) 030 ohms. 10.000 ohms.

230.000 ohms. 50,030 ohms. 103,000 ohms. 300,000 ohms. 150 ohms.

ohms.

47 ohms. 50,000 ohms. 50,000 ohms. 100,000 ohms. 100,000 ohms.

The tube 114 was a type 604; a 12AU7 was used for the dual triode 136; the control tubes 40C and 162 were 6Y6; the dual triode auxiliary tube 60Cwas a type 5687; and .a 6AQ5 was used for the shaper tube 180. i

The foregoing examples, which are well suited to attain the ends and objects of theinvention, have been set forth to explain the principles of the invention in accordance with the requisite statutes. llt will be clear, however, that the embodiments of the invention are adapted to be modified in many different ways so as to best suit the requirements of each particular use, and that certain features of the invention can be used to advantage at times without a corresponding use of other features.

What is claimed is:

1. Apparatus for producing a control current corresponding to a control potential comprising an amplifier connectible to a source of control signals and having input and output circuits, a rnulti-element vacuum tube having an anode, a cathode, a control electrode, and a screen grid, means couplingan output circuit of said amplifier to said control electrode, an anode-cathode negative feedback circuit means responsive to the total of both said screen and plate currents of said tube and being coupledto an input circuit of said amplifier.

2. Apparatus for producing a control current corresponding to a control potential comprising an amplifier connectible to a. source of control signals and having input and output circuits, a multi-element vacuum tube having an anode, a cathode, a control electrode, and

A series with said energizing circuit and said tube, a current control device having a second control element and connected in series with said current-utilizing means and being between said anode and said screen grid, voltage supply means connected to said second control element,

and negative feedback circuit means responsive to the sum of the currents through said anode and through said control device and being coupled to an input circuit of said amplifier.

3. Apparatus for producing a control current corresponding to a control potential comprising an amplifier connectible to a source of control signals and having input and output circuits, a multi-element vacuum tube having an anode, a cathode, a control electrode, and a screen grid, means coupling an output circuit of said amplifier to said control electrode, an anode-cathode energizing circuit for said tube including a source of uni-directional voltage, current-utilizing means connected in series with said energizing circuit and said tube, a current control device having a control element and connected in circuit in series with said current-utilizing means and being between said anode and said screen grid, voltage supply means connected to said control element of said current control device, resistance means connected in series with said anode-cathode circuit of said tube and also in series with the current control device, and a feedback control circuit coupling the voltage developed across said resistance means to the input circuit of said amplifier.

4. Apparatus for controlling an electric current as a function of a control voltage comprising an amplifier connectible to a source of control signals and having input and output circuits, a first multi-element vacuum tube having an anode, a cathode, a control electrode,

' and a screen grid, circuit means coupling the output circuit of the amplifier to said control electrode, an anode-cathode energizing circuit for said tube including a source of direct voltage, current-utilizing means conand said screen grid of said first tube, bias supply means connected to said control electrode of said second tube resistance means connected in series with said anodecathode circuits of both said tubes, thereby to carry the sum of the currents through theanode-cathode circuits of both tubes, and a feedback circuit coupling the volt- I age developed across said resistance means to an input circuit of said amplifier.

5. Apparatus for controling an electric current as a function of a control voltage comprising an amplifier connectible to a source of control signals and having input and output circuits, a first multi-element vacuum tube having an anode, a cathode, a control electrode, and a screen grid, means coupling an output circuit of said amplifier to said control electrode, an anode-cathode energizing circuit for said tube including a source of direct voltage, current-utilizing means connected in series with said energizing circuit and said tube, a second multi-elernent vacuum tube having a cathode, an anode, and a control electrode and having its anodecathode circuit connected between said anode and said screen grid of said first tube, a voltage divider circuit connected to said direct voltage source for supplying bias to said control electrode of said second tube, re-

sistance means connected in series with the anode-cathode circuit of said tube and also in series with the anode cathode circuit of the second tube, whereby said resistance means carries the currents through both tubes, and

' electrode, and a screen grid, means coupling an output circuit of said amplifier to said control electrode, an

anode-cathode energizing circuit for said tube including a source of. uni-directional voltage, current-utilizing means connected in series with said' energizing circuit and said tube, an energizing circuit for said screen grid coupled to said anode, said energizing circuit'being effectively in series with said current-utilizing means,

.whereby both the screen and plate currents of said who pass through saidcurrent-utilizing means, and direct current negative feedback circuit means responsive to the total 'ofboth said screen and plate currents of said tube and being coupledto an input circuit of said amplifier. I 1

7. Current control apparatus comprising a direct current amplifier connectible to a source of control signals and having in put'and output circuits, a multi-element vacuum tube having an anode, a cathode, a control electrode, and a screen grid, means coupling an output circuit of said amplifier to said control electrode, an anodecathode energizing circuit forsaid tube including a source of direct voltage, current-utilizing means connectedin series with said' energizing circuit and said tube, resistance means connected between the cathode of said tube and said'energizing circuit, a feed-back circuit coupling the'volta'ge developed across said resistance means to an input circuit ofsaid amplifier, a second multi-elem'ent vacuum tube having a cathode,-an

I anode, and acont'rol electrode, and having its anodecathode circuit connected between said anode and said screen grid of said first tube, and bias supply means connected to said control'electrode of said second tube.

8. Current control apparatus comprising an amplifier connectible to a source of control signals and having input and output circuits, a first multi-element vacuum tube having an anode, a cathode,qa controlelectrode, and a screen grid, means coupling said control electrode to an output circuit of said amplifier, an anodecathodeenergizing circuit for said tube including a source of direct voltage, current-utilizing means connected in series Wtih said energizing circuit, and said tube, a second multi-element vacuum tube having a cathode, an anode, and a control electrode, and having its anode-cathode circuit connected between said anode and said screen grid of said first tube, coupling means between said control electrode of said second tube and an output circuit of said amplifier for supplying bias voltage to said second tube control electrode, resistance means connected in series with the anode-cathode circuit of said first tube and also in series with the anodecathode circuit of said second tube, and a feed-back circuit'coupling the voltage developed across said resistance means ,to the input circuit of said amplifier;

9. Apparatus for producing a control current corresponding to a control potential comprising an amplifier connectible to a source of control signals and having input and output circuits, a multi-element vacuum tube having an anode, a cathode, a control electrode, and a screen grid, means coupling an output circuit of said amplifier to said control electrode, an anode-cathode energizing circuit for said tube including a source of direct voltage, an inductive load circuit connected in series between said energizing circuit and said tube, an energizing circuit for said screen grid coupled to said anode in series with said inductive load, whereby both the screen and plate currents of said tube pass through said inductive load, and a negative feedback. circuit 9 responsive to both the screen and plate currents of said tube and connected to the input circuit of said amplifier.

10. Apparatus for producing a control current corresponding to a control potential comprising an amplifier connectible to a source of control signals and having input and output circuits, a first multi-element vacuum tube having an anode, a cathode, a control electrode, and a screen grid, means coupling an output circuit of said amplifier to said control electrode, an anode-cathode energizing circuit for said tube including a source of direct voltage, an inductive load circuit connected in series between said energizing circuit and said tube, a second multi-element vacuum tube having a cathode, an anode, and a control electrode, and having its anodecathode circuit connected between said anode and said screen grid of said first tube, bias supply means connected to said control electrode of said second tube, a voltage regulator tube interposed between said cathode and said control electrode of said second tube, resistance means conected in series with the anode-cathode circuits of both tubes, and a feed-back circuit connected from said resistance means to an input circuit of said amplifier.

11. Control apparatus for maintaining the current through an inductive load proportional to a control potential comprising a direct current amplifier having an input circuit composed of first and second terminals and an output circuit composed of third and fourth terminals, said first terminal being connected through a first isolation resistor to a source of control signals, said second and fourth terminals being connected to a common ground circuit, a pentode tube having an anode, a cathode, a control electrode, a screen grid, and a suppressor grid, said third terminal being connected to said control electrode, said suppressor grid being connected to said cathode, said cathode being connected to said second terminal through a second isolation resistor, a resistor connected between said cathode and said common ground circuit, a triode tube having an anode, a cathode, and a control electrode, said anodes of said tubes being connected together and through an inductive load to a source of uni-directional potential, said cathode of said triode tube being connected to said screen grid of said pentode tube, and said control electrode of saidtriode tube being connected to a variable voltage divider interposed between said source of uni-directional potential and said common ground circuit.

12. Apparatus for varying the current through an inductive load in accordance with a control potential comprising, in combination, a source of control signals, a direct current amplifier having an input circuit with first and second terminals and an output circuit with third, fourth, and fifth terminals, a first isolation resistor connected between said first terminal and said source of control signals, said second and fifth terminals being connected to a commonground circuit, a pentode tube having a cathode, an anode, a screen grid, a suppressor grid, and a control grid, said cathode and said suppressor grid being connected together and to said first terminal through a second isolation resistor, said control grid being connected to said fourth terminal, a resistor interposed between said cathode and said common ground circuit, a triode tube having an anode, a cathode, and a control grid, said cathode of said triode being 10 connected to said screen grid of said pentode tube, said control grid of said triode being connected to said third terminal, circuit means connecting said anodes together, and an inductive load interposed between said anodes and a source of unidirectional potential.

13. Apparatus for controlling the current through an inductive load proportional to a control potential comprising, in combination, a source of control signals, a direct current amplifier having an input circuit with first and second terminals and an output circuit composed of a load resistor having variable tap positions thereon and connected between the final stage of said amplifier and a source of negative direct potential, said first terminal being connected through a first isolation resistor to said source of control signals, said second terminal being connected to a common ground circuit, a pentode tube having an anode, a cathode, a screen grid, a control grid, and a suppressor grid, said cathode and said suppressor grid being connected together and to said first terminal through a second isolation resistor, circuit means connecting said control grid to one of the variable taps of said output circuit, a resistor connected between said cathode and said common ground circuit, a triode tube having an anode, a cathode, and a control grid, said cathode of said triode being connected to said screen grid of said pentode tube, and said control grid of said triode tube being connected to one of the variable taps of said output circuit, means connecting said anodes together, and an inductive load connected between said anodes and a source of positive unidirectional potential.

14. Apparatus for producing a control current through the control Winding of a controllable inductor corresponding to a control potential comprising a controllable inductor having a control winding, an amplifier connectible to said control potential and having input and, output circuits, a multi-element vacuum tube having an anode, a cathode, a control electrode, and a screen grid, an anode-cathode energizing source for said tube connected in circuit through the control winding of the controllable inductor to the anode-cathode circuit of said tube, a screen-grid energizing circuit coupled from said anode-cathode circuit to said screen grid, said screen-grid energizing circuit being in series with the control winding, with both the anode and screen-grid currents of said tube passing through the control winding, and a negative feedback circuit responsive to the total of both said anode and screen-grid currents of said tube coupled to an input circuit of said amplifier, said negative feedback circuit including means providing a characteristic compensating for the control characteristic of the control win-ding.

References Cited in the file of this patent UNITED STATES PATENTS 2,251,973 Beal Aug. 12, 1941 2,341,232 Norton Feb. 8, 1944 2,538,488 Volkers Jan. 16, 1951 2,572,832 Bernard Oct. 30, 1951 2,662,125 Stafford Dec. 8, 1953 2,678,391 Lappin May 11, 1954 FOREIGN PATENTS 139,237 Austria Oct. 25, 1934 

